DE102011082663A1 - Scanning module of a position measuring system - Google Patents

Abstract

The invention relates to a scanning assembly of a position measuring system, comprising a radiation source (4) for generating electromagnetic radiation, by means of which a material measure of the position measuring system can be scanned, with a support (1) of the radiation source (4) to which the radiation source (4) can be fixed and the electrical conductor elements (3) for electrical contacting of the radiation source (4), and with electrical connection elements (44, 46) of the radiation source (4), via the radiation source (4) with the conductor elements (3) of the carrier (1 ) is in electrical contact. In this case, the conductor elements (3) of the carrier (1) and the connection elements (44, 46) of the radiation source (4) form a guide on which the radiation source (4) before its fixing to the carrier (1) while maintaining the electrical contact between the radiation source (4) and the conductor elements (3) along an adjustment path (B) with respect to the carrier (1) is movable in order to arrange the radiation source (4) in different positions along that adjustment path (B) on the carrier (1) can in which the radiation source (4) in each case is in electrical contact with the conductor elements (3).

Description

The invention relates to a scanning assembly of a position measuring system, for example a length measuring system, according to the preamble of claim 1.

Such a scanning module comprises a radiation source for generating electromagnetic radiation, for example in the form of a light-emitting diode (LED), by means of which a material measure of the position measuring system, for example a measuring scale in the measuring direction (longitudinal) extending, a measuring graduation having scannable; and a carrier of the radiation source to which the radiation source can be fixed and which has electrical conductor elements for electrical contacting of the radiation source. That is, by the determination of the radiation source to the carrier, this is on the one hand integrated into the Abtastbaugruppe and fixed within this and on the other hand electrically connected, so that the radiation source for generating electromagnetic radiation can be energized. For this purpose, the radiation source on electrical connection elements, via which it is in electrical contact with the conductor elements of the carrier when it is intended to be fixed to the carrier.

Such a scanning subassembly is usually designed as a so-called scanning head, which enables highly precise position determination by (photoelectric) scanning of an associated measuring graduation of the position measuring system.

The measuring graduation to be scanned can be provided on an elongated scale, for example for forming a so-called length measuring system, or extend along a circular path on a graduated disk or on the inner or outer circumference of a drum to form an angle measuring system. Furthermore, the measuring graduation to be scanned by means of the scanning module can be designed both as an incremental graduation and as an absolute code.

A position measuring device with a scanning subassembly of the type mentioned in the form of a scanning or sensor head is known from the DE 198 43 155 A1 known. This head is formed as a Molded Interconnect Device (MID) with a resin molding block substrate coated with a conductive film patterned to form interconnecting lines that extend three-dimensionally on the block , In an opening of the block, an LED is embedded, which serves for the photoelectric scanning of a scale associated with the sensor head and which is connected via electrical connection elements with connecting lines on a surface of the block.

The light emitted by such a radiation source, for example in the form of an LED, is regularly collimated by means of a lens and then passes through a scanning plate as a parallel light beam before it strikes the graduation to be scanned. For precise collimation of the light emitted by the radiation source, the precise adjustment of the distance between the radiation source and the lens used for collimating (condenser lens) is of importance.

The invention is based on the problem to provide a Abtastbaugruppe of the aforementioned type, which enables a simple positioning of the radiation source on the associated carrier with simple means.

This problem is solved according to the invention by the provision of a scanning subassembly having the features of claim 1.

Thereafter, the conductor elements provided on the carrier and the associated connection elements of the radiation source form a guide, by means of which the radiation source is movable along an adjustment path with respect to the carrier before its attachment to the carrier (while maintaining the electrical contact between the radiation source and the carrier-side conductor elements) to be able to arrange the radiation source on the carrier in different positions along the adjustment path, in which the radiation source is in electrical contact with the conductor elements of the carrier, that is each can be energized to generate light.

In this way, the radiation source can be selectively positioned on the carrier so that it has a certain distance to an associated lens and / or scanning, wherein the radiation source is electrically contacted in the respective set position and thus in each case immediately ready for operation in an attachment in the corresponding position ,

The guidance of the radiation source along the adjustment path must by no means take place exclusively by means of the guidance formed by the carrier-side electrical conductor elements and the radiation-source-side electrical connection elements. Rather, a guide device (in addition) may also be formed in that the radiation source is guided with its housing in a corresponding receptacle of the carrier defined along an adjustment path movable. In such a case, the (electrical) guide formed by the conductor and connecting elements may possibly be limited in their function, while a (given by the inclusion of the carrier) movement of the radiation source along the adjustment path to maintain the electrical contact between the radiation source and the carrier-side conductor elements.

According to one embodiment of the invention, the guide formed by the conductor elements and the associated connection elements at least one along the adjustment path extending conductor track and an associated electrical contact element which are displaceable along that adjustment path to each other while being in electrical contact with each other to the radiation source in different Relative positions with respect to the carrier can each contact electrically.

In particular, two printed conductors may be provided in this case, to each of which a contact element is assigned, since a radiation source regularly has at least two electrical connections.

In this case, the respective conductor track can be provided as an electrical conductor element on the carrier, while the respective associated contact element is arranged as an electrical connection element to the radiation source.

The guide can be designed for a rectilinear guided movement of the radiation source by extending the at least one conductor element and / or the associated connection element in a straight line.

The radiation-source-side connection elements can be formed by connection legs projecting from the radiation source or can also be equipped in another way, for example as connecting elements extending on a housing of the radiation source.

Concrete embodiments of the carrier-side conductor elements and the associated radiation-source-side connection elements will be described below with reference to the figures.

For the possible determination of the radiation source on the carrier in a plurality of different positions, in which the radiation source is in electrical contact with the carrier-side conductor elements, fastening methods are particularly suitable, which can be applied steplessly or in small increments in (nearly) arbitrary relative positions, such as Soldering, in particular laser soldering, gluing or other cohesive connections.

The connection between radiation source and carrier can take place on the one hand between the carrier-side conductor elements and the associated electrical connection elements and / or on the other hand between the housing of the radiation source and an associated carrier-side recording. In the former case, the use of electrically conductive connection means, such as an electrically conductive adhesive, appropriate.

In particular, the scanning module can be embodied as a so-called MID device ("Molded Interconnect Device" or molded connection device) in that electrical conductor tracks run on a base body of the carrier made of electrically insulating material, in particular in the form of a device applied to the base body of the carrier Filmes, the electrical contacting on the support arranged electrical components, such as the radiation source serve.

In MID, the injection-molded plastic carrier z. B. selectively provided with electrical conductor elements. These conductor elements can be applied according to known manufacturing processes, such as, for example, printing technology, hot stamping technology, LSA technology, laser direct structuring and two-component injection molding. If the conductor elements are electrolessly deposited on the carrier, they can be reinforced in a further process step by a galvanic deposition process.

Further details and advantages of the invention will become apparent in the following description of exemplary embodiments with reference to the figures.

Show it:

1A a length measuring system consisting of a scale and a scanning head with a scanning module designed according to the invention;

1B a cross section AA of the length measuring system according to 1A ;

2A a support of the scanning module with conductor tracks for contacting on the support to be arranged electrical components;

2 B the carrier off 2A together with a radiation source arranged thereon and electrically contacted;

3 a first modification of the carrier 2A ;

4A a second modification of the carrier 2A ;

4B the carrier off 4A together with a radiation source arranged thereon and electrically contacted;

4C the scanning module off 4B arranged on a circuit board.

The 1A shows a perspective view and 1B a cross section AA of a position measuring system in the form of a length measuring system with a scanning head 10 and a measurement graduation to be scanned thereby 50 (Material measure) of a scale 5 , The length measuring system is used to measure the position of two movable measuring objects in measuring direction X. In this case, the scanning head 10 on one of these measurement objects and the scale 5 attached to the other of the two measurement objects. For a better representation of the structure of the scanning head 10 is in this 1A only the lower part of the housing 9 shown. The scanning head 10 has a scanning assembly 11 on which a carrier 1 with a positioned and mechanically fixed and electrically contacted radiation source 4 includes. Advantageous details and possible configurations of this scanning module 11 will be described below with reference to the others 2A to 4C explained in more detail.

The radiation source 4 emits electromagnetic radiation in the form of light radiation, with which the measurement graduation 50 is palpable. The course of a light beam L is in 1B shown. The position measurement from the radiation source 4 emitted light reaches a lens 6 which forms it, for example collimated, and further on the measurement graduation 50 directed. The light beam L is from the measurement graduation 50 depending on the relative position between the scanning head 10 and the scale 5 modulates and finally reaches a detector array 7 for generating position-dependent electrical scanning signals. The electrical scanning signals can via an electrical line 8th be transmitted to a subsequent electronics.

It will now be based on the 2A to 4C three different embodiments of a scanning module 11 shown leading to the formation of in the 1A and 1B schematically shown scanning head 10 can serve, in particular those components of a scanning head 10 that the recording and energization of the radiation source 4 serve, by means of which the for scanning the associated scale 5 used electromagnetic radiation is generated.

2A shows a carrier 1 such a scanning assembly, the one of an electrically insulating material, for. As plastic, existing body 2 comprises, on which a plurality of (electrically conductive) conductor elements in the form of (metallic) conductor tracks 3 is applied. The main body 2 can be provided by a method known in the MID technique with the conductor elements, for example by coating the body 2 with an electrically conductive film and possibly structuring of the film. As material for the conductor elements (conductors 3 ) is, for example, copper, tin, lead or gold.

The main body 2 of the carrier 1 includes a carrier area 20 from which a recording 22 which stands out a receiving space 23 for the radiation source 4 , see. 2 B , Are defined. The recording 22 , which is formed in the embodiment of a hollow cylinder, extends along a direction of movement B, along which the associated radiation source 4 in the recording 22 is insertable. For this purpose, the radiation source 4 in the embodiment with a substantially hollow cylindrical housing 40 , see. 2 B , provided so that they are within the intake 22 defined recording room 23 can be arranged and along the extension direction of the recording 22 which in the exemplary embodiment coincides with the cylinder axis, along a direction of movement B is movable. The direction of movement B thus defines an adjustment path for possible movements of the radiation source 4 relative to the carrier 1 which can generally have both a (at least partially) rectilinear as well as a curved course.

According to a synopsis of 2A and 2 B is the radiation source 4 in the form of an LED in the receptacle 22 of the carrier 1 such along a direction B, in the embodiment along the longitudinal axis of the hollow cylindrical receptacle 22 runs, movably mounted, that the radiation source 4 , viewed along the direction of movement B, in different positions within the receptacle 22 or the receiving space formed thereby 23 can be arranged, depending on how deep the radiation source 4 in the recording 22 or in the recording room 23 is introduced.

The recording 22 thus forms a guide device for guiding the radiation source 4 when inserted into the recording room 23 and also with a movement (displacement) of the radiation source 4 in the recording room 23 to the radiation source 4 , along the direction of movement B, in a defined position within the receiving space 23 to arrange. The recording 22 is designed slotted in the embodiment, so that form several separated by slots portions (jaws), which is when the radiation source 4 exert a radial bias and the radiation source 4 radially, ie, in directions perpendicular to the direction of movement B, (as far as possible free play) clamp and position.

The electrical contacting of the radiation source 4 on the carrier 1 is facilitated by the said MID technology, by attaching to the consisting of an insulating material, in particular plastic body 2 of the carrier 1 conductor tracks 3 , z. B. in the form of film-like coatings are provided. These form in the embodiment on the one hand connection areas 32 over which the from the carrier 1 and the radiation source 4 existing assembly with the tracks of a circuit board P is electrically contacted. Furthermore, the carrier-side conductor tracks form 3 connecting areas 34 . 36 for electrical contacting of the radiation source 4 ,

The conductor tracks, which those connection areas 34 . 36 form, run in the embodiment of the 1A and 1B on protrusions 24 . 26 of the carrier 1 , which is on both sides of the picture 22 extend, in the present case along the direction of movement B, along which the radiation source 4 in the recording 22 insertable and within the receiving space 23 is displaceable.

For electrical contact with the conductor tracks 3 of the carrier 1 , in particular the connection areas provided for this purpose 34 . 36 the tracks 3 , points the radiation source 4 serving as contact elements connection elements 44 . 46 on. These are in the embodiment of the back 42 of the housing 40 the radiation source 4 from; ie, from the side 42 the radiation source 4 , which when properly introducing the radiation source 4 in the recording 22 from the recording room 23 points away.

The connection elements 44 . 46 are designed as (pin-like) connecting legs, which are bent or unwound that sections 44A . 46A the connection elements 44 . 46 the connection areas 34 . 36 the tracks 3 cross and rest on it. This forms the connection areas 34 . 36 the tracks 3 and the connection elements 44 . 46 the radiation source 4 a guide, specifically in the embodiment, a longitudinal guide which a displacement of the connection elements 44 . 46 on the connection areas 34 . 36 the tracks 3 allowed while the connection elements 44 . 46 continuing with the tracks 34 . 36 to be in electrical contact.

Thus, when adjusting the position of the radiation source 4 within the recording 22 or the recording room 23 the electrical contact between the radiation source and the conductor tracks 3 of the carrier 1 and be maintained over this with the electrical circuits on the associated circuit board P.

By moving or moving the radiation source 4 within the recording 22 of the carrier 1 can change the position of the radiation source 4 in the recording room 23 be set so that certain, predetermined distances to other functional elements of the Abtastbaugruppe be achieved, such as a certain distance of the radiation source 4 from an associated lens arrangement (condenser lens), the parallelization (collimation) of the radiation source 4 used in operation light serves. Additionally or alternatively, for example, a certain distance of the radiation source 4 be adjusted by an associated scanning. The electrical contacting of the radiation source 4 via the connection elements 44 . 46 and the connection areas (along the direction of movement B) 34 . 36 the carrier-side conductor tracks 3 Make sure that in each selected position of the radiation source 4 the desired electrical contact exists to the radiation source 4 be able to supply with electrical energy.

For fixing the radiation source 4 in a desired position within the recording 22 can on the one hand a determination of the electrical connection elements 44 . 46 on the tracks 3 or their connection areas 34 . 36 done, z. B. by soldering, in particular laser soldering, or gluing (by means of an electrically conductive adhesive). Basically, any connection methods are suitable for this purpose, the most infinite or low-level determination of the connection elements 44 . 46 at the connection areas 34 . 36 the tracks 3 enable.

Additionally or alternatively, the radiation source can thereby also in the recording 22 be fixed, that their housing 40 on the wall of the recording 22 is determined. These are in the wall of the recording 22 fixing areas 22A . 22B provided in the form of recesses whose edge is coated in the embodiment with a metallic material. Again, different connection methods can be used, preferably in turn stepless or small-scale connection methods, such. As soldering (laser soldering) or gluing and other cohesive connections.

3 shows a modification of the carrier 2 out 2A with an electrically insulating base body 2 , on the turn ladders 3 , z. B. in the form of film-like coatings are applied. These form on the one hand connection areas 32 to the electrical connection of the carrier 1 to a printed circuit board and also connection areas 34 . 36 for electrical contacting of a radiation source, which is intended within the receiving space 23 a recording 22 of the carrier 1 is arranged.

The recording 22 of the carrier 1 extends in the embodiment of 3 again along a direction of movement B, with an axis of the recording 22 coincides along which a radiation source intended in the recording 22 insertable and within the receiving space 23 is movable (movable).

The recording 22 is in the embodiment of 3 in cross-section (eg substantially perpendicular to the direction of movement B) rectangular in shape, with rounded corners. It is still in the exemplary embodiment of a carrier area 20 of the basic body 2 so that it extends along the direction of movement B.

Another difference to the embodiment of 2A is that the connection areas 34 . 36 the carrier-side conductor tracks 3 about which a designated in the recording 22 arranged radiation source is electrically contacted before recording 22 are arranged, more precisely in an imaginary extension of the recording room 23 along the direction of movement B. The connection areas 34 . 36 the tracks 3 are specific to projections 24 . 26 provided, which, along the direction of movement B, in front of the receiving space 23 the recording 22 lie.

For electrical contacting of a radiation source 4 , compare 2 B , The connecting elements in the form (pin-like) connecting legs in the present case are substantially rectilinearly from the back 42 of the housing 40 the radiation source 4 stand out, so that they are at the intended location of the radiation source 4 in the recording 22 of the carrier 1 according to 2 at the connection areas 34 . 36 the tracks 3 issue.

In contrast to the arrangement of 2A and 2 B is the embodiment of the 3 the extension direction of the conductor tracks 34 . 36 and the associated connection elements 44 . 46 the radiation source 4 formed leadership not primarily by the extension of the connection areas 34 . 36 given (as in the case of 1A and 1B ) but rather by the extent of the radiation source 4 protruding connecting elements (connecting legs) along the direction of movement B.

In the present embodiment, a part forms 28 the recording 22 one (through slots of adjacent areas of the receptacle 22 remote) radially resilient portion (jaws / tab), which on the radiation source 4 exerts a radial pressure and this during the guide in the direction of movement B in the recording 22 as free of play as possible positioned in directions perpendicular to the direction B.

In the 4A to 4C is another embodiment of a conductor tracks 3 provided vehicle 1 ( 4A ), whose electrically insulating body 2 a recording 22 defines in which a radiation source 4 is arranged ( 4B ), taking from the carrier 1 , the tracks 3 and the radiation source 4 existing assembly is disposed on a printed circuit board P and thereby integrated into an electrical or electronic circuit ( 4C ).

According to the 4A and 4B indicates the basic body 2 of the carrier 1 a carrier area 20 on, from which the recording 22 protrudes along a direction of movement B. The recording 22 is in the embodiment of 4A and 4B in cross-section polygonal with rounded corners. It in turn defines a recording room 23 , within which a radiation source 4 can be arranged, extending along the direction of movement B in the recording 22 or the recording room 23 can be introduced.

For electrical contacting of the radiation source 4 and to the electrical connection of the carrier 1 to the circuit board P are on the body 2 Conductor elements in the form of printed conductors 3 provided, on the one hand connection areas 32 to connect to circuit board side tracks and on the other hand connecting areas 34 . 36 for electrical contacting of the radiation source 4 ,

From the connection areas 34 . 36 the carrier-side conductor tracks 3 runs a connection area 34 along a wall area 24 the recording 22 and another connection area 36 at a projection 26 , which is next to the picture 22 extends, in the direction of movement B.

For electrical contacting of the radiation source 4 with the two extending in the direction of B connection areas 34 . 36 the carrier-side conductor tracks 3 can thus on the one hand directly on the housing 40 the radiation source 4 lying connection element 44 ' serve, which when properly arranged the radiation source 4 inside the recording room 23 with the in the recording 22 of the basic body 2 integrated connection area 34 the tracks 3 in electrical contact, and on the other hand, a contact element 46 in the form of one of the radiation source 4 protruding pin-like connecting leg, which is bent in such a way that it with a section 46A along the associated connection area 36 the tracks 3 extends.

By the extent of the radiation source 4 to be contacted connecting areas 34 . 36 the carrier-side conductor tracks 3 along the direction of movement B, along which the radiation source 4 the recording 22 insertable and within the receiving space 23 is positionable, the electrical contact between the radiation source remains 4 and the carrier-side conductor tracks 3 during a movement or displacement of the radiation source 4 within the recording 22 with the goal of a defined positioning of the radiation source 4 persist permanently. The radiation source side connection elements 44 ' . 46 and carrier-side connection areas 34 . 36 the tracks 3 So again form a longitudinal guide.

As in the case of the embodiment of 2A and 2 B can also in the case of 3 as well as the 4A to 4C a fixation of the radiation source 4 be done in a previously set position characterized in that the connection elements 44 ' . 46 the radiation source 4 at the associated connection areas 34 . 36 the carrier-side conductor tracks 3 be set, for. B. by soldering, in particular Läserlöten, gluing or other cohesive use method.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19843155 A1 [0005]

Claims (14)

Scanning assembly of a position measuring system, comprising - a radiation source ( 4 ) for generating electromagnetic radiation, by means of which a material measure ( 50 ) of the position measuring system is scanned, - a carrier ( 1 ) of the radiation source ( 4 ) at which the radiation source ( 4 ) and the electrical conductor elements ( 3 ) for electrical contacting of the radiation source ( 4 ), and - electrical connection elements ( 44 . 46 ) of the radiation source ( 4 ), via the radiation source ( 4 ) with the conductor elements ( 3 ) of the carrier ( 1 ) is in electrical contact, characterized in that the conductor elements ( 3 ) of the carrier ( 1 ) and the connection elements ( 44 . 46 ) of the radiation source ( 4 ) form a guide at which the radiation source ( 4 ) prior to its attachment to the carrier ( 1 ) while maintaining the electrical contact between the radiation source ( 4 ) and the ladder elements ( 3 ) along an adjustment track (B) with respect to the carrier ( 1 ) is movable to the radiation source ( 4 ) in different positions along that adjustment path (B) on the carrier ( 1 ), in which the radiation source ( 4 ) each in electrical contact with the conductor elements ( 3 ) stands. Scanning assembly according to claim 1, characterized in that the guide at least one conductor track ( 34 . 36 ) and an associated electrical contact element ( 44 . 46 ) which are displaceable relative to one another along the adjustment path (B) and in this case are in electrical contact with one another, so that the radiation source ( 4 ) in different relative positions with respect to the carrier ( 1 ) is electrically contacted. Scanning subassembly according to Claim 2, characterized in that the guide has two printed conductors (9) extending along the adjustment path (B). 34 . 36 ) and associated electrical contact elements ( 44 . 46 ) having. Scanning assembly according to claim 2 or 3, characterized in that the at least one conductor track ( 34 . 36 ) as an electrical conductor element on the carrier ( 1 ) is provided and that the respectively associated electrical contact element as a connection element ( 44 . 46 ) at the radiation source ( 4 ) is provided. Scanning subassembly according to one of the preceding claims, characterized in that the guide is designed for a rectilinear guided movement of the radiation source ( 4 ). Scanning assembly according to claim 5, characterized in that the for electrical contacting of the radiation source ( 4 ) connecting sections ( 34 . 36 ) of the conductor elements ( 3 ) and / or the respective associated connection element ( 44 . 46 ) are rectilinearly extended. Scanning subassembly according to one of the preceding claims, characterized in that at least one connecting element ( 44 . 46 ) of the radiation source ( 4 ) by one of the radiation source ( 4 ) projecting connecting leg is formed. Scanning subassembly according to one of the preceding claims, characterized in that at least one connecting element ( 44 ' ) of the radiation source ( 4 ) on the housing ( 40 ) of the radiation source ( 4 ) is trained. Scanning assembly according to one of the preceding claims, characterized in that the carrier ( 1 ) a recording ( 22 ), at which the radiation source ( 4 ) is arranged and along the adjustment path (B) is movable. Scanning assembly according to claim 9, characterized in that connecting areas ( 34 . 36 ) of the carrier-side conductor elements ( 3 ), the electrical contacting of the radiation source ( 4 ) via their connection elements ( 44 . 46 ), next to the picture ( 22 ). Scanning assembly according to claim 9, characterized in that connecting areas ( 34 . 36 ) of the carrier-side conductor elements ( 3 ), the electrical contacting of the radiation source ( 4 ) via their connection elements ( 44 . 46 ), before recording ( 22 ). Scanning assembly according to one of the preceding claims, characterized in that for determining the radiation source ( 4 ) on the carrier ( 1 ) the connection elements ( 44 . 46 ) cohesively with connection areas ( 34 . 36 ) of the carrier-side electrical conductor elements ( 3 ) are connected. Scanning assembly according to one of the preceding claims, characterized in that the carrier ( 1 ) a body consisting of an electrically insulating material ( 2 ), on which the conductor elements ( 3 ) extend as interconnects. Scanning assembly according to one of the preceding claims, characterized in that the radiation source ( 4 ) a lens ( 6 ) is assigned to that of the radiation source ( 4 ) to collimate emitted electromagnetic radiation, and that required for the collimation distance between the radiation source ( 4 ) and lens ( 6 ) by moving the radiation source ( 4 ) with regard to the carrier ( 1 ) is adjustable along the adjustment path (B).

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